Dietary cosupplementation with vitamin E and coenzyme Q(10) inhibits atherosclerosis in apolipoprotein E gene knockout mice.

Intimal oxidation of LDL is considered an important early event in atherogenesis, and certain antioxidants are antiatherogenic. Dietary coenrichment with vitamin E (VitE) plus ubiquinone-10 (CoQ(10), which is reduced during intestinal uptake to the antioxidant ubiquinol-10, CoQ(10)H(2)) protects, whereas enrichment with VitE alone can increase oxidizability of LDL lipid against ex vivo oxidation. In the present study, we tested whether VitE plus CoQ(10) cosupplementation is more antiatherogenic than either antioxidant alone, by use of apolipoprotein E-deficient (apoE-/-) mice fed a high-fat diet without (control) or with 0.2% (wt/wt) VitE, 0.5% CoQ(10), or 0.2% VitE plus 0.5% CoQ(10) (VitE+CoQ(10)) for 24 weeks. None of the supplements affected plasma cholesterol concentrations, whereas in the VitE and CoQ(10) groups, plasma level of the respective supplement increased. Compared with control, plasma from CoQ(10) or VitE+CoQ(10) but not VitE-supplemented animals was more resistant to ex vivo lipid peroxidation induced by peroxyl radicals. VitE supplementation increased VitE levels in aorta, heart, brain, and skeletal muscle, whereas CoQ(10) supplementation increased CoQ(10) only in plasma and aorta and lowered tissue VITE: All treatments significantly lowered aortic cholesterol compared with control, but only VitE+CoQ(10) supplementation significantly decreased tissue lipid hydroperoxides when expressed per parent lipid. In contrast, none of the treatments affected aortic ratios of 7-ketocholesterol to cholesterol. Compared with controls, VitE+CoQ(10) supplementation decreased atherosclerosis at the aortic root and arch and descending thoracic aorta to an extent that increased with increasing distance from the aortic root. CoQ(10) significantly inhibited atherosclerosis at aortic root and arch, whereas VitE decreased disease at aortic root only. Thus, in apoE-/- mice, VitE+CoQ(10) supplements are more antiatherogenic than CoQ(10) or VitE supplements alone and disease inhibition is associated with a decrease in aortic lipid hydroperoxides but not 7-ketocholesterol.

Rigorous swim training impairs mitochondrial function in post-ischaemic rat heart.

The effect of rigorous swim training (6 h day-1, 5 days week-1 for an average of 191 h) on mitochondrial respiratory function was investigated in rat heart subjected to in vivo ischaemia reperfusion (I-R). Mitochondria was isolated from the risk region of the left ventricle subjected to 60 min occlusion of the main left coronary artery followed by 30 min reperfusion. Heart weight and heart-to-body weight ratio was increased by 21 and 28% (P < 0.01), respectively, in the trained (T, n = 15) vs. control rats (C, n = 20). I-R per se showed minimal effect on heart mitochondria regardless of training status. In sham, state 4 respiration rate was 26 and 32% (P < 0.05) lower in T vs. C rats, using malate-pyruvate (M-P) and 2-oxoglutarate (OG) as substrates, respectively. Training also reduced state 3 respiration by 28% (M-P) and 50% (OG) (P < 0.01). The respiratory control index (RCI) was unaltered in T with M-P, but decreased with OG (P < 0.01). In vitro exposure to superoxide radicals severely reduced state 4 and 3 respiration and RCI, but T hearts showed greater reductions of state 4 and 3 rates than C. Mitochondria from T hearts also revealed a greater state 4 inhibition by H2O2 and HO. compared with C. A lower glutathione content and a higher gamma-glutamyl transpeptidase activity (P < 0.05) was observed in T vs. C. It is concluded that rigorous swim training impairs heart mitochondrial function, making them more susceptible to in vivo and in vitro oxidative stress, and that this damaging effect may be related to a diminished glutathione reserve.

Ischaemia-reperfusion induced alterations of mitochondrial function in hypertrophied rat heart.

The impact of in vivo ischaemia and ischaemia-reperfusion (I-R) on mitochondrial respiratory function was investigated in hypertrophied (HP) hearts with aortic constriction compared with control hearts using an open-chest rat surgical model. Moreover, mitochondrial susceptibility to superoxide radicals (O2-.) in vitro was examined in HP and control hearts with or without I-R. With the site I substrates pyruvate-malate, mitochondrial state 4 (basal) respiration and the respiratory control index (RCI) were not affected by either ischaemia alone or I-R in both HP and control hearts. State 3 (ADP-stimulated) respiration was increased with I-R in control hearts, but showed a reduction after I-R in the HP hearts. Exposure of mitochondria to O2-. (20 nM hypoxanthine in the presence of 0.13 unit mL-1 xanthine oxidase) significantly increased state 4 respiration, whereas state 3 respiration and RCI were decreased in all treatment groups. I-R hearts in both HP and control showed greater increases in state 4 respiration with O2-. than either sham or ischaemic hearts. HP hearts exhibited a significantly lesser extent of inhibition in state 3 respiration and RCI by O2-. compared with control hearts. These changes in mitochondrial respiratory properties were not observed with the site II substrate succinate. Myocardial reduced vs. oxidized glutathione ratio was significantly decreased after I-R in both control and HP hearts. Malondialdehyde content showed an increase with I-R, but the increase was significant only in control hearts. These data indicate that short-term in vivo I-R does not impair heart mitochondrial respiratory function, but renders the organelles more vulnerable to imposed oxidative stress. Mitochondria from the HP hearts are more resistant to free radical damage under normal and ischaemic conditions; however, this advantage is severely compromised after reperfusion.